波浪板理论在多个相互作用游泳运动员中的推广

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2023-07-07 DOI:10.1002/cpa.22113
Peter J. Baddoo, Nicholas J. Moore, Anand U. Oza, Darren G. Crowdy
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引用次数: 3

摘要

西奥多森、冯·卡尔曼、吴等人的分析解决方案极大地推动了空气动力学和生物推进的早期研究。虽然这些经典解决方案仅适用于孤立的游泳者,但多个游泳者之间的流动相互作用与许多实际应用有关,包括动物集体的教育和群集。在这项工作中,我们导出了一类描述二维无粘性流体中任意数量游泳者之间流体动力学相互作用的解。我们的方法植根于多重连接复杂分析,并利用了最近的几个结果。具体而言,超越(Schottky–Klein)质函数是构造适当的共形映射和前缘吸力函数的基本构建块,这使我们能够解决出现的修正Schwarz问题。因此,我们的解决方案将经典的薄机翼理论,特别是吴的波浪板分析推广到多个游泳者的情况。对于一对相互作用的游泳者的情况,我们开发了一种有效的数值实现,可以快速计算每个游泳者身上的力。我们研究了流介导的平衡,发现我们的新解决方案与之前报道的实验结果之间非常一致。我们的解决方案恢复并统一了文献中不同的结果,从而为未来研究多个游泳者之间的相互作用打开了大门。
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Generalization of waving-plate theory to multiple interacting swimmers

Early research in aerodynamics and biological propulsion was dramatically advanced by the analytical solutions of Theodorsen, von Kármán, Wu and others. While these classical solutions apply only to isolated swimmers, the flow interactions between multiple swimmers are relevant to many practical applications, including the schooling and flocking of animal collectives. In this work, we derive a class of solutions that describe the hydrodynamic interactions between an arbitrary number of swimmers in a two-dimensional inviscid fluid. Our approach is rooted in multiply-connected complex analysis and exploits several recent results. Specifically, the transcendental (Schottky–Klein) prime function serves as the basic building block to construct the appropriate conformal maps and leading-edge-suction functions, which allows us to solve the modified Schwarz problem that arises. As such, our solutions generalize classical thin aerofoil theory, specifically Wu's waving-plate analysis, to the case of multiple swimmers. For the case of a pair of interacting swimmers, we develop an efficient numerical implementation that allows rapid computations of the forces on each swimmer. We investigate flow-mediated equilibria and find excellent agreement between our new solutions and previously reported experimental results. Our solutions recover and unify disparate results in the literature, thereby opening the door for future studies into the interactions between multiple swimmers.

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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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